FI128222B - Reading room for RFIDs - Google Patents

Abstract

The invention relates to a reading room (100) for RFID tags. The reading room installation base (1) comprises a horizontal bottom (12) which circulates the inner side (T) of the reading room (100), which bottom consists of a number of connected bottom segments (121, 122, 123, 124), to which the bottom is connected a number of vertical support (14), - the lower end of each wall (3) of the wall element (31) is arranged in the grooves (12c) of the base (1) of the base (1) and in addition, the two end sides (31a, 31a) of each wall (3) are arranged in the (1) grooves (14a) vertically supported (14) between at least one bottom segment (121, 122, 123, 124) and the lower end of the wall element (31) provided with a seal (7) which attenuates radio frequency interference, such as a EMC seal, - The RFID tag reading means (6) include an antenna and a data processing system by which RFID tags can be read.

Description

The invention relates to a read space for RFID tags according to the preamble of claim 1.

The invention also relates to an RFID tag reader according to claim 15.

The invention further relates to the use of an RFID tag read space to control the passage of persons with RFID tags.

The reading modes of the RFID tags should be as interference-free as possible for external RF emissions and yet the reading sensitivity itself should be as good as possible. These are conflicting goals because increasing the read sensitivity of RFID tags in read mode also increases the sensitivity of off-mode RFID tags. By improving the manufacturing tolerance and sealing of the components alone, it is difficult to improve the isolation of the reading space without significantly increasing the manufacturing / installation costs of the reading space.

The above also has the disadvantage that as the accuracy of sealing increases, the reading space installation speed drops dramatically, as sealing between the mounting base and the walls becomes more laborious the better sealing is sought.

The above prior art as a starting point for the invention was to provide a read space for 20 RFID tags that would be as vulnerable as possible to

For read-only interference caused by RFID tags, but where the manufacturing tolerances of the walls and the mounting base should not be made too tight. In addition, the invention was intended to provide a reading space whose sealing between the mounting base (base beams, uprights and top supports) and the walls would be simple and quick to install.

The invention relates to a read space for RFID tags as defined in claim 1.

More particularly, the invention relates to an RFID tag reading space having a ceiling, a floor, at least one door, and walls surrounding the reading space including a plurality of interconnected wall elements, and a wall and door / door mounting platform, and means for reading the RFID tags in the reading space. Then read mode

- the mounting base comprises a horizontal base rotating from the inside of the reading room, consisting of a plurality of interrelated bottom segments, the base being associated with a plurality of vertical supports,

20185156 prh 25 -10- 2018 each mounting platform bottom segment and the vertical support consist of a groove beam with grooves of grooves consisting of a groove bottom having recesses facing away from the groove, in addition, both ends of each wall are disposed in a groove in the vertical support of the mounting platform,

- a radio frequency interference suppression seal, such as an EMC seal, extending parallel to the groove base of a groove beam comprising said base segment, and also at least one vertical groove edge of a wall element mounted on said base segment and between the at least one vertical segment fitted with a radio frequency interference suppression seal, such as an EMC seal, extending parallel to the groove base of the groove beam comprising said vertical support, such that said radio frequency interference suppression seal extends substantially continuously from the bottom segment to the groove wall,

The RFID tag reading means comprises an antenna and a data processing system capable of reading the RFID tags.

In a preferred embodiment of the invention, the mounting base further comprises a horizontal mounting base 20 of the mounting base which is connected to the upper end of the vertical supports and is formed by a groove beam having a groove formed by a groove base having recessed groove walls extending in each direction transverse to said groove.

- one of the groove walls of the upper support is provided with a radio frequency interference suppression joint, such as an EMC seal, which runs parallel to the groove base of the groove bar,

- the upper end of each wall wall element is disposed in the groove of the upper base of the mounting base so that the above-mentioned radio frequency interference suppression gasket rests against the upper end of the wall, respectively.

The invention also relates to the RFID tag reader 30 of claim 15.

More particularly, the invention also relates to a reading space for RFID tags having a ceiling, a floor, at least one door, and walls surrounding the reading space comprising:

20185156 prh 25 -10-2018 a plurality of interconnected wall elements, as well as a wall and door / door mounting base, and means for reading RFID tags in a reading space, the mounting base comprises a horizontal base rotating inside the reading space consisting of a plurality of associated base segments. This base is associated with a plurality of vertical supports 5, wherein each base segment of the mounting base and the vertical support consist respectively of a beam having a projection upwards or sideways from the horizontal plane of the beam and extending longitudinally of the beam in question.

The lower end of the wall element, as well as both ends thereof, has an elongated groove formed by a groove base, the two edges of which are joined by groove walls extending away from the groove base 10, both of which are transverse to the direction of said groove base.

- the groove on the lower end of the wall element and the grooves on each end side thereof are arranged respectively in the projection of the base segment of the mounting base and the projection of the vertical support

- at least one radio frequency interference suppression seal, such as an EMC seal, extending parallel to the recess, is provided between the groove of the lower end of each wall element and the projection of the base segment of the mounting base, and

- at least one radio frequency interference suppression seal, such as an EMC seal, extending longitudinally of the vertical support, is also provided between the groove on each end face of the wall element and the corresponding vertical support projection,

The RFID tag reader means comprises an antenna and a data processing system capable of reading the RFID tags.

In a preferred embodiment of the invention as defined in claim 15, the mounting base further comprises a bottom base mounting base associated with an upper end of the vertical supports and consisting of a beam having a beam 25 downwardly extending an elongated groove formed by a groove bottom, the two edges of which are joined by groove walls extending away from the groove bottom, each of which is transverse to the direction of said groove bottom,

- the groove of the top end of each wall wall element and / or the top end of the door frame top member is disposed in said projection of the mounting base upper support,

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an elongated radio frequency interference suppression seal, such as an EMC seal, extending parallel to the groove of the top end of each wall element, is provided between at least one groove wall of the top end groove wall and a projection of the top support.

The invention is based on the fact that the read mode for RFID tags used for remote identification of radio frequency identifiers (i.e., RFID tags) has been disrupted by read-out interference caused by out-of-area RFID tags by centralizing any wall fabrication inaccuracies in the mounting base. Step 10 alternatively, the inaccuracies in the manufacture of the base are centered in the grooves in the wall elements of the walls.

In this case, the precision of manufacture of either the wall elements or the mounting platform can be compromised and still provide much better interference suppression inside the RFID tag reading space. This provides the significant advantage that the reader accuracy of the RFID tag reader can be increased without being exposed to reading errors caused by out-of-reading RFID tags.

In a preferred embodiment of the invention, the reading space according to the invention has at least one door comprising a door element and a door frame rotating the door element. The lower part of the door frame is fitted into the groove in the base of the mounting base. In addition, each side member of the 20 door frames is disposed in a groove in the vertical support of the mounting base such that said RF interference suppression seal is supported on the lower member or the side member of the door frame, respectively.

In another preferred embodiment of the invention, the reading space of the invention has at least one door comprising a door element and a door frame rotating the door element. The lower part of the door frame and each side member of the door frame have a groove formed by a groove base, the two edges of which are joined by groove walls extending away from the groove base, each of which is transverse to the direction of said groove base. Thus, at least one groove wall of the lower part of the door frame and at least one groove wall of each of its side members 30 is provided with a radio frequency interference suppression seal, such as

EMC seal which runs parallel to the groove base of said groove. Here

- each side member of the door frame is disposed on the stand of the mounting bracket so that the at least one radio frequency interference suppressing seal mentioned above is also in contact with the bracket of the mounting bracket, and

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the lower part of the door frame is disposed in the base segment of the base of the mounting base so that the at least one radio frequency interference suppressing seal mentioned above is also in contact with the projection of the base base of the base of the base.

The inventor has found that the biggest problems with the read space of RFID tags are caused by the exiting of the RF signals from the reading space through the defective seals on the door. The invention employs a similar arrangement of manufacturing inaccuracies for doors as for wall elements and the base of a mounting base: any inaccuracies in the manufacture of doors are centered in the groove of the mounting base or in the grooves in the door frames.

Radio frequency interference suppression seal means an elongated seal made of an electrically conductive material such as metal. A typical conductive EMC gasket is an aluminum sealing tape. The sealing can also be done with the interlocking / molded parts of the wall elements and the mounting base, if the wall elements and the mounting base are both made of conductive material, at least as far as they come into contact.

Radio frequency interference refers to radio frequency interference wavelengths between 3 Hz and 300 GHz.

In one preferred embodiment of the invention, the radio frequency interference suppression seal 20 runs continuously from the groove wall of the groove bottom of the base of the mounting platform to the groove wall of the two associated vertical supports and further to the groove wall of the upper support.

When a wall element is mounted on a mounting base with such a mounting base seal, the advantage is obtained of providing a continuous sealing around the front face of the wall member, which effectively prevents radio frequency waves from entering the reading space.

In yet another preferred embodiment of the invention, the radio frequency interference suppression gasket extends continuously from the projection of the base section of the base of the mounting base to the upright projection and further to the projection of any top support.

When a wall element end face and a horizontal bottom and top face are fitted to a projection of a mounting base with such a mounting base seal, the advantage is obtained of providing a continuous end face of the wall element and

20185156 prh 25 -10-2018 lower and upper page rotation seal, which effectively prevents radio frequency waves from entering the reading space.

In another preferred embodiment of the invention, the radio frequency interference suppression seal runs continuously from the groove wall 5 of the groove bottom of the base of the mounting base to the groove wall of the two associated vertical supports and further to the groove wall of the groove support.

In another preferred embodiment of the invention, the radio frequency interference suppression seal extends continuously from the projection of the base segment of the base of the mounting base to the projection of the upright support and further to the projection of the frame support.

When a wall element and a door frame are fitted to a mounting base with such a seal, a seal is provided between the wall element and the mounting base and between the mounting base and the door frame to prevent radio frequency waves from passing through the wall element and / or door frame.

By "continuous seal" is meant that the seal may contain small openings in the seal but not direct discontinuities where the seal would be broken.

By using either a mounting base according to the invention having grooved beams which can be fitted with a wall element or wall elements having grooves which can be fitted with projections of a mounting base, an easy and excellent fast sealing structure is achieved; the gasket is easy to install to rotate the mounting base as well as grooves / projections on the wall elements.

The state of the art closest to the invention is disclosed in U.S. Application Publication No. 2017196128 A1, which discloses an RFID read space whose structure, however, differs significantly from that of the RFID read space of the present invention.

In the following, the invention will be illustrated with reference to the accompanying figures.

Figure 1A shows the top support mounted at the bottom of the mounting base and seen from the top.

Figure 1B is a schematic perspective view of the top support viewed from the rear.

Figures 2A and 2B schematically illustrate two principles of groove sealing on beams of a mounting platform.

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Figures 2C-2H schematically illustrate various sealing structures of the projection in the mounting base beam and the groove in the wall.

Figures 2K and 2L schematically illustrate the structures formed by the projection and the groove at the top of the mounting base and in the walls.

Figures 3A and 3B show a top-notch mounting of a vertical support in the bottom corner of the mounting base and a completed bottom corner with a vertical support.

Figures 4A and 4B are perspective views illustrating various vertical supports mounted on both the straight portion of the base of the mounting base and the corner of the base.

Figure 4C schematically illustrates the fabrication of a bottom corner of a mounting base from two bottom segments.

Figure 5 is a side elevation view of an end of a vertical support having an end fitting for mounting a vertical support to the bottom of the mounting base or to the upper support of the mounting base.

Figure 6 is a side elevation view of adjusting the base of the mounting base via the auxiliary mounting base.

Figures 7A and 7B show a front view of a portion of two different RFID tag read modes.

Figures 8A-8D illustrate a top plan view of various mounting platform uses for providing RFID read space.

Figure 9 illustrates, externally, an exemplary read state of RFID tags.

The structures of the vertical support 14, the base 12, the upper support 13, the frame support 15 and the wall elements 31 of the walls 3 used in connection with the mounting base 1 according to the invention are illustrated in Figures 1A-1B, 2A-H, 2K, 2L, 3A-3B, 25A-4C, 5. and 6.

These basic structures of the mounting platform 1 are capable of providing the various RFID tag read states described in Figures 7A-7B, 8A-8D and 9.

1A-1B and 2A-2H, 2K, 2L, the structure of the mounting base 1 and the wall elements to be connected thereto, as well as sealing replacements 30, will first be described.

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Figures 2A and 2B illustrate, with two schematic sectional patterns, the formation of two similar types of seals, respectively,

(a) placing a seal 7 between the groove beam (120, 130 or 140) and the wall element 31; or

b) by placing a seal 7 between a wall element 31 having a groove 311 and a projection 13g protruding from a beam 13 (vertical support).

The exemplary seal shown in Fig. 2A is formed by inserting a seal 7 between the U-groove 12a of the bottom segment of the base segment 12 of the groove beam and the lower end of the wall element 31 fitted to this U-groove 12a. A similar type of seal 10 may also be formed by installing the seal between the U-groove 13 of the upper support 13 comprising the groove beam and the upper end of the wall element 31 or between the U-groove 14 and the end face of the wall element 31. As shown in Fig. 2A, the seal is generally mounted between the lower end of the wall element 31 and the second groove wall of the U-groove of the base segment only.

The exemplary seal shown in Fig. 2B is formed between a projection 13g downwardly from the beam of the upper support 13 and a horizontal groove 31a extending at the top of the wall element 31, which opens upwards. The projection 13g of the upper support 13 is brought close to the groove base 31c of the top groove 31a of the top end of the wall element 31. The seal 7 is disposed on a groove wall 31d facing upwardly from the horizontal groove base 31c; 31 d ”and protrusion 13g. A seal of the same type may again be formed between the upwardly extending projection 12g from the bottom segment 12g of the base 12 and the horizontal groove 311 at the lower end of the wall element 31 which opens downwardly or laterally from the upright 14 to the lateral end groove 311.

Fig. 1B illustrates the installation of a seal 7 on a groove beam 140. The groove beam 140 can then be used to form a seal of Fig. 2A between the groove beam 140 and the lower end 31 of the wall element, as will be described later.

Fig. 1B shows (seen from the rear) a groove beam 140 that can be used as a vertical support 14. An underside end fitting 8 of Fig. 1B extends from below the lower edge of the groove beam 140; 80. The shown groove beam 140 can be supported through the lower end support surface 80a of its end fitting 80 to the groove base 12c of the groove beam 120 of the bottom segment as shown in Figure 1A.

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The vertical support 14 shown in Fig. 1B consists of a groove beam 140 having a U-shaped groove 14a (U-groove) consisting of a groove base 14c having a groove wall 14 extending away from the groove base 14c at each of its longitudinal edges; 14d 'and 14; 14d '. Each of the vertical supports 14 has a groove wall 14; 14d 'and 14; 14d 'extends away from the groove base 14c of the U-groove 14a at an angle of approximately 90 degrees, with each groove wall 14; 14d 'and 14; The plane passing through 14d 'is transverse to the plane of the groove base 14c.

Fig. 1A shows the groove beam 140 (vertical support 14) of Fig. 1B having a U-groove 14a. This U-groove 14a engages the bottom 12 via an adapter 8. The fitting 8 comprises an internal fitting 8 for the stop 14; 90 and an end fitting 8 seamlessly connected to the inner fitting; 80a. Access Adapter 8; 80a is supported in the groove base 12c of the groove 12a of the base 12 of the mounting base.

In Figure 1A, only one of the two groove walls 14d of the vertical support 14; 14d ', extends parallel to the groove base 14, i.e. vertically, about said groove wall 14; 14d "15" continuous EMC gasket 7; 7a which conducts electricity. Suitably, the EMC gasket is an aluminum band.

The purpose of the EMC seal is to seal the clearance between the wall element 31 to be mounted on the vertical support 14 and the groove wall 14d of the U-groove as illustrated in Fig. 2A so that the EMC seal 7 is not; 7a passes 20 radio frequency radiation from inside the space to the outside or vice versa. As shown in Figure 1A, the upright support 14 is supported by the end fitting 8; 80, to the groove base 12c of the mounting bracket 12, the vertical EMC gasket extends to the groove wall 12d of the base 12. This groove wall 12d is then mounted with its own EMC gasket horizontally. Figure 1A does not show the seals of the groove 12c of the base 12 for simplifying the figure.

The seals 7 of the groove 12c of the base 12 and their connection to the seals 7 of the vertical support 14 are shown e.g. 3A-3B and 4A-4B.

Accordingly, Figures 3A-3B and 4A-4B show in more detail the EMC30 gasket 7 running in particular on the base 12 of the mounting base, parallel to the groove base 12c of one of its base segments; 7a which comes in contact with the vertical support 14 with the EMC gasket (cf. Fig. 1A).

As shown, inter alia, in Figure 3B, the seal 7 thus forms a continuous sealing strip 7 ", 7 'extending from the groove 12a of the bottom segment 12 to the vertical support 14 of the bottom segment. The groove 14a of the vertical support 14 and the groove 12a of the bottom segment are in contact

20185156 prh 25 -10-2018 through its groove walls 14d ", 12d ', whereby the sealing strip extends from the groove wall 12" of the bottom segment groove to the groove wall 14d of the vertical support 14. The advantage of such a continuous sealing strip 7 ", 7 'is that it effectively prevents radio frequency radiation from propagating to the opposite side of the sealing strip despite minor inaccuracies in the manufacturing tolerances of the wall element 5 31, base 12 or upright 14, their normal perpendicular position relative to one another.

Figures 2C-2E show various upwardly directed upward projections 12g of the bottom segment of the base 1 from the longitudinal to horizontal 12h (horizontal).

Figures 2K and 2L, in their turn, schematically illustrate the structures formed by the projection and the groove in the segments 12 of the base of the mounting base and in the roof structures (upper support 13) and the vertical support 14.

Figures 2C-2E are schematic sectional views showing various projections 12g from the longitudinal plane 12h (horizontal plane) of the base 15 of the base 1. The projections 12g always extend perpendicular to the horizontal plane 12h, which is parallel to the substrate on which the bottom segment is supported. A similar projection 12g may also be provided in the upper support 13, whereby it is directed downwardly from the upper support and at the same time perpendicular to the plane of the roof, as shown in Fig. 20 2B. A similar projection 12g may also be provided on the upright 14, wherein the projection is vertical and extends sideways from a vertical plane defined by the upright 14 in the direction of the bottom segment attached to the upright 14.

Figures 2K and 2L illustrate various grooves extending at the top or bottom of the wall element 31 or at the end of the wall element 31, respectively (cf. Figure 2B). Accordingly, a protrusion engaging the bottom segment 21, 22, 23, 24, the upper support 13 or the vertical support 14 may be mounted thereon, as shown schematically in FIG. 2B and 2C-2E.

Fig. 2K illustrates how a horizontal projection 14g of the type shown in Fig. 2C protruding from an upright 14 can be mounted in a vertical groove 411 extending at the end of the wall element 31 by sealing between the sealing projection 14g and the groove wall 411 at the end of the wall element 31.

Fig. 2L illustrates the effect of providing a seal according to the invention to a joint formed by vertical projections 12g in the segments 121 and 122 of the base 12 of the mounting base 1 and wall elements 31; 31 'and 31;

20185156 prh 25 -10-2018 ”. Each wall element 31; 31 'and 31; A downwardly extending groove 311 is formed in the 31 "lower end 31 f; 311 'and 311; 311 ", each of which extends 12g from the plane of the base segment 121, 122; 12g 'or 12g; 12g ”is adjustable. Wall elements 31; 31 'and 31; 31 'appear mounted on their lower end 31 f horizontal scales 311; 311 'and 311; 311 ', respectively, to the two projections 12g from the bottom 121.122 of the bottom segment 12; 12g 'and 12g; 12g ". These projections 12g; 12g 'and 12g; 12g ”and wall element 31; 31 'and 31; The space between the horizontal grooves 311 of the 31 "lower ends 31f is sealed by an EMC gasket 7 which is here an aluminum tape / tape.

In addition, Figure 2L shows each of the wall elements 31; 31 'and 31; 31 'at the top end, more particularly at the top end 31d of the top end, a horizontal U-groove 311 opening upwards; 311 and 311; 311 These include wall elements 31; 31 'and 31; 31 ”to horizontal arms 311; 311 and 311; A 311 "" is fitted with a top bracket 13 having two downward projections 7 from this top bracket 13 (see also FIG. 2D).

A downwardly extending projection 13g of the upper support 13; 13g 'or 13g; 13g ”and 311 horizontal scales; 311 "'and 311; 311 "" is a horizontal horizontal EMC gasket 7; 7a.

Gasket 7; 7a is mounted on the vertical side of the horizontal groove reading space T of the wall element 31 and extends continuously in the groove 311 of the top end 31d of the wall element 31 and in the projection 13g of the top bracket 13. When the groove 311 of the upper end 31 d of the wall element 31 is fitted to the projection 13g of the upper support 13, the transmission of radio frequency radiation to the reading space T through the groove 311 of the upper support is prevented, for example. Thus, a sealing strip consisting of seals 7 extends continuously from the projection 13g of the upper support 13 of the mounting base 1 to the projection 14g of each of the two lateral supports 14 (not shown) and further to the projection 12g of the bottom segment 12 of the base 12.

Figures 3A-3B, 4A-4B also illustrate vertical support pairs 14, 14 mounted on segments 12 of the base 12 of the mounting bracket 1, whose C-groove openings 14b, 14b open at either 90 or 180 degrees to each other.

Fig. 4C, in turn, shows the corner of the base 12 of the mounting bracket where the two right-angled base segments 121,122 enter.

Fig. 5 shows a structure of an upright support 14 according to a preferred embodiment of the invention, with an upright 14a having an adapter 8 for engaging said upright support 14 with a horizontal groove 12a or 13a of the base 12 and / or upper support 13.

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3A-3B, 4A-4B, 4C and 5 illustrate the vertical support pairs 14, 14, the vertical support 14 adapters 8 and the base 12 segments to provide easily and quickly sealable structures between the mounting base 1 and the wall elements 31 and door frames 15 to be fitted thereto. These structures will be described below in the following, and comprise various interconnections between interconnected uprights and bottom segments.

Figure 4C shows how segments 121 and 122 of base 12 are interconnected such that their bottoms run in the same horizontal plane but have longitudinal angles of 90 degrees, i.e. at right angles to each other. The right angle between the bottom segments 10 121,122 allows a pair of upright supports 14,14 to be mounted at an angle (corner) therebetween, with the vertical grooves 14a, 14a opening 90 at an angle to each other as illustrated in Figures 3B and 4A.

4C, the corner of the base 12 shown in FIG. 4C is formed by two bottom segments 121 and 122 of the base 12 interconnected at a 90 degree angle. Each bottom segment 121, 122 of the base 15 12, as well as the entire base 12, is formed by a groove beam 120. The groove 12a of the groove beam 120 is formed by a groove base 12c having grooves 12d extending away from the groove base. 12d and 12d; 12d 'each having a direction transverse to the direction of said groove base 12c. Near the second groove wall 12d of groove beam 120; 12d 'upper 20, running through a continuous elongated strip-like seal 7 made of an electrically conductive material such as metal. The seal 7 follows said groove wall 12d; 12d ', thus passing along the longitudinal direction of the groove base. The seal 7 preferably extends from end to end of the groove beam 120.

Figures 3B and 4A show a pair of upright supports 14 pre-installed in two grooves 12a 25 of the bottom segment 121,122 of the base 12; 14 'and 14; 14 "having the openings 14b, 14b 'and 14b of the vertical supports; 14b 'open at 90 degrees to each other. Figure 3A, in turn, shows a pair of upright supports 14; 14 'and 14; 14 ”is mounted at 90 ° to the bottom segments 121,122 of the bottom 12. The bottom segments 120, 121 are interconnected in the same manner as the one illustrated above in FIG. 4C.

Fig. 4B shows two vertical supports 14 mounted in the groove 12a of the same base segment 121 of the base 12; 14 'and 14; 14 ”, with openings 14b, 14b opening 180 at an angle to each other. Such a pair of vertical supports 14 ', 14' is mounted on the bottom

20185156 prh 25 -10-2018 and can be used, for example, as an intermediate support for mounting the door 5 to the base segment of the mounting base later as illustrated in Figure 7B.

3A-3B and 4A-4B; 14 'and 14; 14 ”rear walls can be connected to each other before installation. Figures 3A-3B and 4A-4B illustrate a pair of upright supports 14 of interconnected uprights; 14 'and 14; 14 "each upright support 14 ', 14" consists of a groove beam 140 similar to that described above with reference to Figures 1A and 1B. In turn, the groove beam 120 of the bottom segments shown in Figures 3A-3B and 4A-4B is similar in structure to that described in more detail in Figure 4C.

Fig. 5 shows a structure of a vertical support 14 according to a preferred embodiment of the invention, with an adapter for attaching an adapter for engaging the vertical support 14 to the base 12 and / or the upper support 13. This is illustrated by two similar vertical longitudinal supports 14 shown in Fig. 14 'and 14; 14 ”, 15 each consisting of a groove beam 140. A groove beam 140; 140 'and 140; The 140 ”structure is similar to that previously described with reference to Figure 1A. 140 for each groove bar; 14 'and 140; 140 "140 above the upper end 14f of the lower part (or upper part) of the lower part (or upper part), the end fitting 80 shown in the figure rises. Said vertical supports 14; 14 'and 14; 14 'are connected to each other in the same manner as the vertical supports shown in Figures 3A-3B 20 and 4A-4B, wherein the rear wall of the first vertical support 14: 14' groove wall 14d engages with the second vertical support 14; 14 ”to the back wall of the groove base 14c.

The end fitting 80 is part of an assembly 8 pre-attached to the groove 14a of the upright support 14 for attaching the upright support 14 to the bottom 12. The fitting 8 has an end fitting and an end fitting 80 shown in Fig. 25.

140 of the grooves 14a from the outer edges 14f, 14f of the groove base 14c and the ends of the groove walls 14d, 14d in the direction of the groove 14a for a given distance (protrusion) 80h. End adapter 8; The 80 protrusion 8h corresponds to the depth of the groove 12a of the bottom 12 or the groove 13a of the upper support 13, i.e. in practice the vertical le30 of the groove walls 12d or 13d of the bottom groove 12a or upper support groove 13a. Vertical support 14 EMC gasket 7; 7a is here longer than the groove walls 14d and the groove base 14c of the slightly upright support 14. In this case, the seal 7; 7a extends from the upper edge (outer edge) of the groove wall 14d of the vertical support 14 to about halfway up the length (protrusion) 80h of the end fitting 80.

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The vertical support 14 is mounted on the groove beam 120 of the base 12 via said adapter 8 such that the end support surface 80a of the end fitting 80 is supported on the groove base 12c of the base groove 12a or the groove base 13c of the groove 13a of the upper support 13. In this case, the gasket 7 parallel to the groove wall 14d of the vertical support 14; 7a extends to a seal 7 extending from the bottom 12 or the upper support 13 to the wall 12d or 13d 5 following the upper edge of the wall. The length 7a is dimensioned such that it extends all the way to the horizontal seal 7 passing through the groove wall 12d or 13d of the groove beam 120 or 130 of the bottom 12 or the upper support 13.

If the upper and lower ends of the groove beam 140 of the vertical support 14 are provided with an end support 80, 80, the lower end adapter 80 of the groove beam 140 can support the groove base 12c of the groove 12a of the bottom segment 10 and the upper upper adapter 80

13a to the groove base 13c. In this case, a gasket 7 parallel to the vertical support 14, parallel to the groove wall 14d; 7a extends through the bottom 12 of the bottom 12 and the top 7 of the bottom 13, following the upper edge of the wall 12d and 13d, thereby providing a continuous seal 70 from the bottom segments 14 of the bottom 12 to the upright 13.

Fig. 6 shows the arrangement used for rectifying the base 12. In this, an auxiliary mounting base 9, such as a rigid metal foil, is mounted under the bottom of the base 12 of the base. The base of the mounting base is then adjusted by means of screws supporting the auxiliary mounting base and a spring between the screws relative to the ground or the base of the building 20.

Figures 7A and 7B show two wall elements 31 of wall 3, respectively; 31 'and 31; 31 "(Fig. 7A) and a wall element 31 and a door 5 (Fig. 7B) mounted on a pair of vertical supports 14 in the corner formed by segments 121 and 122 of the base 12; 14 'and 14; 14 ".

In this case, the vertical supports 14 formed of groove beams 140; 14'and 14; The 14 "openings also open at an angle of 90 degrees away from each other in the direction of the groove beams 12c, 12c of the bottom segments 121 and 122 of the groove beams 12. This is done by pairs of interconnected vertical supports 14; 14 'and 14; 14 "and the structure of the bottom segments 121, 122 of the base 12 are similar to those previously described in Figures 30A-1B, 3B and 4B, 4C. In this case, each pair of vertical supports 14; 14 'and 14; The 14 "vertical support consists of interconnected groove beams 140 ', 140" having a structure similar to that previously described, for example, with reference to Figures 1A and 1B. Also, the bottom bottom segments 121 and 122 each consist of groove beams 120 having the same structure as previously described, for example, in connection with the description of Figures 1A and 1B.

20185156 prh 25 -10- 2018

7A, each of the wall elements 31; 31 'and 31; 31 'is coupled to a mounting base 1 comprising a pair of aforementioned vertical supports 14 at an angle t in the corner formed by the bottom segments 121, 122; 14 'and 14; 14 ', a vertical support 14 is also connected to the ends of each bottom segment 121 and 122, the opening 14b of which is pivotally perpendicular to the vertical support at one end of the bottom segment.

Exemplary Fig. 7A shows only a pair of upright supports 14; 14'and 14; 14 "as viewed from a third vertical support 14 connected to one end 121a of the bottom segment 121; 14 ''. Vertical support 14; 14 '' consists of a groove beam 140 '' having a structure similar to that previously described, for example, with reference to Figures 1A and 1B.

The "orifice 14b" of the vertical support 14 'is pivoted directly to the vertical support 14 at the opposite end of the segment 121 of the base 12; 14 '.

In addition, the mounting bracket 1 includes a horizontal upper bracket, not shown in the figure, associated with the vertical brackets 14; 14 'and 14; 14 ”through the end fitting at the top of the vertical supports (not shown in the figures).

The grooves 120 forming the bottom segments 121 and 122 of each base 12; 120 'and 120; 120 "is a fitted radio frequency interference suppression gasket 7, preferably an EMC gasket. Gasket 7 extends from end to end of said groove beam 120 'and 120 "parallel to the groove base (horizontally). Also, each of the vertical supports 14; 14 ', 14 "and 14'" forming a groove bar 140; The groove walls (12d, 14d) of the grooves 20 (12a, 14a) of the 140 ', 140' and 140 '' groove 20 are provided with a radio frequency interference suppression seal 7, such as an EMC seal. A seal 7 passes through each of the vertical supports 140; 140 ', 140 "and 140'" parallel to the groove base 12c, 14c, i.e. vertically extending each of the vertical supports 14; 14 ', 14 "and 14'" forming groove bar 140; 140 ', 140 "and 140'" for bottom and top end fittings (not shown) as illustrated in Figure 5.

Vertical supports 14; 14 ', 14 "and 14'" are mounted in grooves 120 of the bottom segments of the base 12; 120 'and 120; 120 ”vertical supports 14; 14 ', 14 "and 14'" via end fittings 80 at the lower end. In addition, each vertical support 14; 14 ', 14 "and 14'" are coupled to horizontal top supports not shown in Fig. 7A, via an end fitting at the top of each vertical support (not shown). Vertical supports 14; 14 ', 14 "and 30 14' 'are also coupled as depicted in FIG. 5, i.e. through an end fitting 80, to the grooves 120 of the bottom segments of the base 12; 120 'and 120; 120 ”and the above head restraints. Then, each of the vertical supports 14; 14 ', 14' 'and 14' 'the seal 7 parallel to the groove wall 14d always extends to the seal 7 following the top 12d or 13d of the bottom 12 or the upper support 13, following the upper edge of the wall 12d or 13d; The length 35a of the 7a is dimensioned to extend to an elongated seal 7 extending in the groove beam 120 of the bottom floor segment or the groove beam 130 of the upper support 13.

20185156 prh 25 -10- 2018

Each vertical support 14; Thus, the seal 7 parallel to the groove wall 14d, 14 'and 14' 'extends to the wall 12d of the bottom segment 121 or 122 of the base 12 and the groove wall 13d of the upper support 13 following the upper edge of the groove wall. In this way, a continuous sealing strip is provided which extends from each base segment 121,122 of the base 5 to each of the vertical supports 14 fitted to these base segments; 14 ', 14 "and 14'" and further to the upper support 13.

Each wall element 31; 31 'and 31; The 31 "lower end is now fitted into the grooves 12c of the base segment 121 or 122 of the base 12 of the mounting base 1. Each wall element 31; 31'and 31; 31 ”both end sides and the side ends adjacent to these end pages are on the other side arranged on the mounting base vertical supports 14; 14 ', 14 "and 14'" in the grooves 14a. Each wall element 31; 31 'and 31; The 31 ”upper end is fitted to the upper supports (not shown in the figures) following the bottom segments 121, 122. The radio frequency interference suppression seals 7 then form a continuous sealing strip extending from each base segment 121, 122 to each of the vertical supports 14; 14 ', 14 "and 14'" and further at the top 13. This sealing strip also rests on the lower end of each wall element 31, each side end adjacent to each vertical side and the top of the wall element, thereby forming a continuous sealing band

Fig. 7B shows a part of a mounting base 1 according to the invention with a door 5. The mounting base 1 first comprises two bottom segments 121,122 which are connected to each other at an angle of 90 degrees and thereby provide a corner of the base 12. The structure of the bottom segments 121, 122 forming the bottom corner and the seals 7 attached thereto are similar to those previously described in Figure 4C.

In these two grooves 12a of the base segment 121,122 of the base 12, 25 a pair of vertical supports 14 are mounted; 14 'and 14; 14 "having the openings 14b, 14b 'and 14b of the vertical supports; 14b 'open at 90 degrees to each other as shown in Figure 3A. The seamless sealing strip rotates from each of the bottom segments 121, 122 to the vertical supports 14; 14 'and 14; 14 "as illustrated in Figures 3A-3B and 4A-4B: An electrically conductive EMC gasket 7, such as an aluminum strip, passes through the bottom segment 121, 122 30 of the base 12 in the direction of the groove base 12c. When the bottom segment 121, 122 comes into contact with the vertical supports 14; 14 'and 14; 14 '(cf. Fig. 1A), a continuous sealing strip extending from the bottom segments 121, 122 of the base 12 to each of the vertical supports 14 is formed.

In addition, two vertical supports 14 and 14 mounted in grooves 12a of the same base segment 121 are formed in the base 12 of the mounting base, the openings 14b, 14b 35 opening 180 at an angle to each other (cf. Fig. 4B). Bottom of the bottom segment

20185156 prh 25 -10- 2018

The seal 121 extends parallel to the groove base 12c, preferably the EMC seal, which comes into contact with the EMC seal of the vertical supports 14, 14 (cf. Fig. 1A). Thereby, a continuous seal 5 is formed from the grooves 12a of the bottom segment 121 of the base 12 to each groove 14b of the vertical supports 14, 14.

This pair of vertical supports 14, 14 mounted in the groove 12a of the same bottom segment 121 can be used, for example, as an intermediate support for mounting the door 5 as follows:

The lower portion 51a of the door frame 51 is disposed in the groove 12a of the base segment 121 of the base 12 of the mounting base 1. The first side member 51b of the door frame 51 is fitted 10 to one of the uprights 14 of the pair of vertical supports; 14 '. The second side member of the door frame 51, in turn, is mounted on one of the uprights 14 mounted on the same groove 12a of the bottom floor segment 121, thereby allowing the radio frequency interference suppression gasket 7 to rest on the lower part 51b, 51b of the door frame 51, respectively. The mounting base 1 further comprises a horizontal frame 15, which is connected to two vertical supports.

The upper frame member 51c of the door frame may be mounted on said frame support: the horizontal frame support 15 is formed by a groove beam 150 having a groove 15a formed by a groove base 15c having two longitudinal sides One of the groove walls 15b of the frame support 15; 15b ', 15b' is a fitted radio frequency interference suppression EMC seal extending parallel to the groove base 15c of the groove beam 150. Thus, the frame support 15 has the same basic structure as the vertical support 14 and the segment 12 of the base 12, both of which also consist of groove beams 140, 120.

The cradle support 15 engages the central or upper end of the vertical supports 14. Its first end engages one of the uprights 14 of the pair of uprights; 14 'and its other end engages another of the uprights 14 mounted on the same groove 12a of the bottom floor segment 121.

The upper door frame member 51c is disposed in the groove (15c) 30 of the frame base 15 of the mounting base 1 so that the radio frequency interference suppression gasket 7 also rests on the upper door member.

Figures 8A-8D show various RFID read modes implemented with bottom and vertical support pairs having a seal according to the invention.

20185156 prh 25 -10- 2018

First, these figures show an RFID tag reading space 100 located in a removable container (Fig. 8A) with an RFID tag storage and two doors 5 inside the reading space 100. The reading space comprises RFID tag reading means 6 comprising an antenna and a data processing system 5 capable of reading RFID tags retrieved from storage. The warehouse is located outside the read space 100, so no error signals should be allowed from the read space. Each reading room door 5, and all wall elements 31 of wall 3; 31 ', 31 ", 31'", 31 "" and the ceiling is fitted to a previously described support frame consisting of groove beams comprising a base 12, a vertical support 14, an upper support 13 and a frame support 14. Mounting base 10, 1 (= support body), the bottom of the uprights, and the top supports karmitukien urapalkkien reading state inside of the side slot wall to rotate always continuous sealing strip, which is made of the EMC seal. The mounting base 1 and the wall elements and doors fitted to it are mounted on the bottom of the container.

Figures 8B and 8C show an RFID tag reading space 100 located in a warehouse or 15 stores with RFID tagged items. In the shop, the door 5 may be a sliding door.

Further, Fig. 8D illustrates the use of RFID tag read space 100 to control the passage of persons with RFID tags.

Figure 9 shows yet another RFID tag reading space 100 provided with a glass door. The reading space shown in Fig. 9 is implemented as described in Fig. 7B and comprises a base 12 having segments 121 and 122 of the base 12, each consisting of a groove beam 120 followed by a continuous EMC seal of electrically conductive material at one of the groove walls. A plurality of vertical support pairs 14, 14, each consisting of a plurality of grooves 140, are coupled to segments 12, 122 of the base 12. A frame support 15 and upper supports are coupled to the upper end of these vertical support pairs

13, which also consist of career beams. Each upright is a pair of 14.14 uprights

14, as well as the frame support 15 are also provided with a continuous EMC gasket as previously described. The EMC gasket rotates as a continuous sealing strip from the first segment 121 of the base to the vertical supports of pairs 14, 14 at the corner of segments 121, 122 and to the second vertical support 14,14 of the pair of segments 121 and further to the frame support 15 and top. In addition, the EMC gasket rotates as a continuous sealing strip from the second segment 122 of the base 12 to each of the vertical supports 14, 14 at the corner of segments 122 and 123 and further to the upper support 13. By fitting the glass door to the groove 140 the groove and the grooves 15 of the frame support 19 are provided with a structure in which the glass door rests on a continuous sealing strip at one of its outer edges. Each wall 31 is mounted as depicted in Figures 7A and 7B in a groove in the bottom 12 segment, a groove 14.14 at the opposite ends of the two segments, and a groove 13 in the top bracket connecting these vertical supports. Thus, each wall 5 is supported by a continuous sealing band at one outer edge extending from the top edge of the groove wall of the bottom segment to the top edge of the groove walls of both vertical supports and further to the top edge of the groove wall of the top support.

20185156 prh 25 -10- 2018

Reference Number List

Mounting base bottom groove

12a orifice groove base groove walls projection bottom longitudinal horizontal bottom segment

12b

12c

12d

12g

12h

121, 122, 123, 124 career bar

120 upper support groove

13a groove base groove wall projection

13c

13d

20185156 prh 25 -10- 2018 groove beam vertical support groove mouth groove groove groove rear

130

14a

14b

14c

14d

14e

20185156 prh 25 -10- 2018 top or bottom (outside) 14f projection14g vertical groove141 groove beam140 frame support15 groove15a groove base15c groove walls15d groove beam150

Katto2

Wall3 Wall Element31 End Page 31a Side End Bound to End End 31 e Front Page 31b Back Side31c Top Side31 d Bottom End 31 F Groove1111 Groove Base311c Groove Wall311d

Lattia4

Door door frame i51 lower door frame51a door frame side51b upper door frame51c

Lukuvälineet6

Radio frequency seal attenuating seal7

EMC tiiviste7a

Sovite8

End fitting80 end fitting support80a end fitting protrusion 80h

Sisäsovite90

Apuasennusalusta9

Reading room100 insideT

Claims (29)

The claims An RFID tag reading space (100) having a ceiling (2), a floor (4), at least one door (5) and walls (3) surrounding a reading space (100) comprising a plurality of interconnected wall elements (31), and a mounting base 5 (1) for walls (3) and door (s) (5), and means for reading RFID tags in a reading space (100), characterized in that - the mounting base (1) comprises a horizontal base (12) rotating the inside (T) of the reading space (100) consisting of a plurality of connected base segments (121, 122, 123, 124), the base being associated with a plurality of vertical supports (14), 10 - each base segment (121,122, 123, 124) of the mounting base (1) consists of a groove beam (120) and also each of the vertical supports (14) consists of a groove beam (140) having grooves (12a, 14a) of grooves (120, 140) , 14c) having at its two edges adjacent groove walls (12d, 14d) facing away from said groove base (12c, 14c), wherein the direction of each groove wall (12d, 14d) is transverse to the direction of said groove base, - the lower end of the wall element (31) of each wall (3) is disposed in a groove (12c) of the base (12) of the mounting base (1) and furthermore both end faces (31a, 31a) of each wall (3) (14a) - at least one bottom segment (121,122, 123,124) and the Between the lower end of the 20 visual elements (31) is a radio frequency interference suppression seal (7), such as an EMC seal extending parallel to the groove base (12c) of a groove beam (120) comprising said bottom segment (121, 122, 123, 124); (121, 122, 123, 124) a groove beam (140) comprising a side member (31e) abutting at least one end face (31a) of the wall element (31) and a vertical support (14) mounted on the same bottom segment (121, 122, 123, 124). between the groove wall (14d) of the groove (14a) is a radio frequency interference suppression seal (7), such as an EMC seal extending parallel to the groove bottom (14c) of the groove beam (140) comprising said vertical support (14), the seal (7) extends substantially continuously from the bottom segment (121, 30 122, 123, 124) for the groove wall (14d) of at least one vertical support (14), The RFID tag reading means (6) comprise an antenna and a data processing system capable of reading the RFID tags. 20185156 prh 25 -10- 2018 A reading space (100) according to claim 1, comprising at least one door (5) comprising a door element and a door frame (51a) rotating the door element, characterized in that the lower part (51a) of the door frame (51) is arranged on the base (12). ) in the groove (12a) of the bottom segment (121, 122, 123, 124) and that each of the door frame (51) The 5 side piece (51b) is disposed in the groove (14a) of the vertical support (14) of the mounting base (1), wherein at least one elongated radio frequency interference suppression gasket (7) is mounted on the lower part (51a) of the door frame 123, 124) between the groove (12a) and at least one elongated radio frequency interference suppression seal (7) is also mounted between each side member (51b) of the door frame (51) and the groove (14a) of the vertical support (14). A reading space (100) according to claim 1, characterized in that the door (5) is a sliding door arranged in a groove in the bottom segment (121, 122, 123, 124) of the base (12) of the mounting base (1). The RFID tag number 15 space (100) according to any one of the preceding claims, characterized in that the mounting base (1) further comprises an upper support (13) parallel to the base of the mounting base (12) connected to the upper end of the vertical supports (14). consisting of a groove beam (130), wherein the groove (13a) of the upper support (13) is formed by a groove base (13c) having grooves walls (13b) facing away from the groove base (13c), each direction transverse to the direction of said groove base (13c), when - the upper end of the wall element (31) of each wall (3) is disposed in the groove (13c) of the upper support (13) of the mounting base (1), and - a radio frequency interference suppression gasket (7), such as an EMC gasket, is arranged between at least one groove wall (13d) of the upper support (13) and the upper end of the wall element (31); 25 running parallel to the groove base (13c) of the groove beam. An RFID tag read space (100) according to any one of the preceding claims, characterized in that - the mounting base further comprises a horizontal frame support (15) connected to the middle or upper end of the vertical supports (14), the frame support (15) consisting of a groove beam 30 (150) having a groove (15a) consisting of a groove base (15c) having at its two edges adjacent groove walls (15b) extending away from the groove base, each of which is transverse to the direction of said groove base (15c), 20185156 prh 25 -10- 2018 - at least one of the groove walls (15d; 15d ', 15d') of the frame support (15) is provided with a radio frequency interference suppression seal (7), such as an EMC seal extending parallel to the groove base (15c) of the groove beam; - the upper part of the door frame is arranged in the groove (15c) 5 of the frame support (15) of the mounting base (1) so that the above mentioned radio frequency interference suppression seal (7) is also supported on the upper part of the door frame. RFID tag reading space (100) according to one of the preceding claims, characterized in that the first radio frequency interference suppression seal (7) extends continuously from the groove wall (12d) of the groove (12a) of the base (12) of the mounting base (1). 10 and two associated vertical supports (14) for the groove wall (14d) of the groove (14a) and further for the groove wall (13d) of the groove (13a) of the upper support (13). RFID tag reading space (100) according to claim 6, characterized in that the second radio frequency interference suppression seal (7) runs continuously from the groove wall (12d) of the groove (12a) of the base (12) of the mounting base (1) 15 (14a) to the groove wall (14d) and further to the groove wall of the groove support (15). The RFID tag reading space (100) according to any one of the preceding claims, characterized in that the vertical support (14) consists of two contact grooves (140). The RFID tag reading space (100) according to claim 8, characterized in that the openings of the groove beams (140), vertical grooves (14a) are directed in opposite directions. The RFID tag reading space (100) according to claim 8, characterized in that the openings of the vertical grooves (14a) of the groove beams (140) are oriented at an angle of 90 degrees to each other. 25 The RFID tag reading space (100) according to any one of claims 8 to 10, characterized in that the groove beams (140) are attached to one another or integrated in one piece. RFID tag reading space (100) according to one of the preceding claims, characterized in that the groove (14a) of the vertical support (14) opens at the bottom of the mounting base (1). 30 ice (12) in the longitudinal direction of the bottom segment (121, 122, 123, 124). The RFID tag reading space (100) according to any one of the preceding claims, characterized in that the vertical support (14) comprises a groove bar (140) having a lower and / or 20185156 prh 25 -10-2018 at the upper end is an adapter (8) for mounting said vertical support (14) in the groove (12a) of the base segment (12) and / or the groove (13a) of the upper support (13). RFID tag reading space (100) according to claim 13, characterized in that the longitudinal seal (7) of the vertical support (14) extends into the groove (12a) of the base (12). 5 and / or a groove (13a) in the upper support (13). A RFID tag reading space (100) having a ceiling (2), a floor (4), at least one door (5) and walls (3) surrounding a reading space (100) comprising a plurality of interconnected wall elements (31), and wall (3) and door (s) (5) mounting platform (1), and means for reading RFID tags in a reading space (100), characterized by: 10 that reading space - the mounting base (1) comprises a horizontal base (12) rotating from the inside (T) of the reading space (100) consisting of a plurality of interrelated base segments with a plurality of vertical supports (14) associated therewith, each base base and vertical support (14) respectively, the bar with the horizontal bar A projection (12g, 14g) upwards or outwards of 15 planes or longitudinally of the beam, - at the lower end of the wall element (31) and at both end sides (31a) thereof there is an elongated groove (311) consisting of a groove base (31c) having at its two edges connected to the groove walls away from the groove base The direction 20 is transverse to the direction of said groove base, whereby the groove (311) of the lower end of the wall element (31) and the groove (311) on each end face (31a) of the wall element (31) are disposed on the projection (12g) of each mounting element. at least one radio frequency interference suppression gasket (7), such as an EMC gasket (71), extending between said lower end groove (311) and the bottom 25 segment (121, 122, 123, 124) of the mounting base (1), 311) at least one radio frequency interference suppressing braid (7), such as an EMC seal (7a), is also provided between the groove base (311c) and the groove (31g) on each end face (31) and the respective projection (14g) of the respective vertical support (14), extending longitudinally of the vertical support (14), The RFID tag reading means (6) comprises an antenna and a data processing system capable of reading the RFID tags. 20185156 prh 25 -10- 2018 A reading space (100) according to claim 15 having at least one door (5) comprising a door element and a door frame (51) rotating the door element, characterized in that the lower part (51a) of the door frame (51) and each side member of the door frame (51) (51b) is a groove formed by a groove bottom with both edges 5 associated with recessed groove walls, each of which is transverse to the direction of said groove and at least one groove wall of the door frame (51) lower part (51a) and at least one groove wall of each of its side members (51b), such as radio frequency interference suppression; An EMC seal extending parallel to the groove base of said 10 grooves, wherein each side member (51b) of the door frame (51) is disposed on a projection (14g) of a mounting base vertical support (14) such that the at least one RF interference suppression seal (7) the vertical support (14) to the projection (14g), The lower part (51a) of the door frame (51) is disposed in the bottom segment (121, 122, 123, 124) of the base (12) of the mounting base (1) such that the at least one radio frequency interference suppression seal (7) is also in contact with the base ) to the bottom segment protrusion (12g). A reading space (100) according to claim 15 or 16, characterized in that the door 20 (5) is a sliding door disposed in a projection (12g) rising from the bottom segment (121, 122, 123, 124) of the base (12) of the mounting base (1). An RFID tag read space (100) according to any one of claims 15 to 17, characterized in that - the mounting base (1) further comprises an upper support (13) parallel to the base (12) of the mounting base (1), connected to the upper end of the vertical supports (14) and consisting of a beam having a horizontal downward projection (13g) of the beam; extending longitudinally of the upper support (13), wherein the upper end of the wall elements (31) of the wall (3) and / or the upper end of the door frame (51) has an elongated groove (311) formed by a groove are transverse to the direction of said groove, 20185156 prh 25 -10- 2018 - an upper groove (311) of the wall element (31) of each wall (3) and / or an upper end groove (311) of the door frame (51) arranged in said projection (13g) of the upper support (13) of the mounting base (1), - at least one groove wall in the groove of the upper end of each wall element (31) of the wall (3), An elongated radio frequency interference suppression gasket (7), such as an EMC gasket (7a) extending parallel to the top groove (311) of said wall element (31), is disposed between the projection (13g) of the upper support (13). The RFID tag reading space (100) according to any one of claims 15 to 18, characterized in that the radio frequency interference suppression seal (7) 10 is continuous from the projection (12g) of the base segment (12) of the base (12) of the mounting base (1) to the projection (14g) of the vertical support (14) associated with the two base segments and further to the projection (13g). RFID tag reading space (100) according to claim 19, characterized in that the radio frequency interference suppression seal (7) runs continuously over the wall. 15 (31) at the lower ends of each end wall of the wall (31). RFID tag reading space (100) according to claim 18 or 19, characterized in that the radio frequency interference suppression seal (7) extends continuously from the projection (12g) of the bottom segment (12g) of the base (12) of the mounting base (1) to the projection (14g). further to the projection of the cradle support (15). 20 RFID tag reading space (100) according to one of Claims 15 to 21, characterized in that the two vertical supports (14) are connected to one another with their projections (14g) facing in opposite directions. An RFID tag reading space (100) according to any one of claims 15 to 21, characterized in that the two vertical supports (14) are connected to one another, 25 so that their projections (14g) are at an angle of 90 degrees to each other. RFID tag reading space (100) according to any one of the preceding claims, characterized in that an auxiliary mounting platform (9) is mounted under the base of the mounting base (12) for adjusting the orientation of the mounting base (12) with respect to the ground or building foundation. 30 The RFID tag reading space (100) according to any one of claims 1-24, wherein the radio frequency interference suppression seal is a metal seal. The RFID tag reading space (100) according to any one of claims 1 to 25, wherein the RF interference suppression gasket is made of a metal such as aluminum and is formed by the bottom segments (121, 122, 123, 124) and vertical supports (14) of the mounting base (12). ) as well as wall mounts connected to them 5 with the interlocking shapes of these elements. An RFID tag reading space (100) according to any one of claims 1 to 26, which is located in a transportable container. An RFID tag reading space (100) according to any one of claims 1-27, which is located in a warehouse or store, where 10 stores have items with RF D-support. Use of an RFID tag reading space (100) according to any one of claims 1 to 28 for controlling the passage of persons with RFID tags.